changed comments & added basic VT100 support

pull/1/head
Ondřej Hruška 10 years ago
parent 877df1a3ed
commit d716190cc5
  1. 6
      lib/adc.h
  2. 6
      lib/arduino_pins.h
  3. 6
      lib/calc.h
  4. 20
      lib/colors.h
  5. 63
      lib/debounce.h
  6. 6
      lib/hsl.h
  7. 36
      lib/lcd.h
  8. 6
      lib/loops.h
  9. 2
      lib/meta.h
  10. 6
      lib/nsdelay.h
  11. 50
      lib/pins.h
  12. 12
      lib/uart.h
  13. 166
      lib/uart_ansi.c
  14. 62
      lib/uart_ansi.h
  15. 31
      lib/ws_rgb.h

@ -1,8 +1,8 @@
#pragma once #pragma once
/* //
Utilities for build-in A/D converter // Utilities for build-in A/D converter
*/ //
#include <avr/io.h> #include <avr/io.h>

@ -1,8 +1,8 @@
#pragma once #pragma once
/** //
Pin definitions for Arduino (Pro Mini with ATmega328P) // Pin definitions for Arduino (Pro Mini with ATmega328P)
*/ //
#include "pins.h" #include "pins.h"

@ -1,8 +1,8 @@
#pragma once #pragma once
/** //
Bit and byte manipulation utilities // Bit and byte manipulation utilities
*/ //
// --- Increment in range --- // --- Increment in range ---

@ -1,15 +1,15 @@
#pragma once #pragma once
/* //
Some useful utilities for RGB color manipulation // Some useful utilities for RGB color manipulation
//
The XXXc macros don't use cast, so they can be used in array initializers. // The XXXc macros don't use cast, so they can be used in array initializers.
//
xrgb ... 3-byte true-color RGB (8 bits per component) // xrgb ... 3-byte true-color RGB (8 bits per component)
rgbXX ... XX-bit color value, with equal nr of bits per component // rgbXX ... XX-bit color value, with equal nr of bits per component
//
XX_r (_g, _b) ... extract component from the color, and convert it to 0..255 // XX_r (_g, _b) ... extract component from the color, and convert it to 0..255
*/ //
typedef struct { typedef struct {

@ -1,37 +1,38 @@
#pragma once #pragma once
/** //
An implementation of button debouncer. // An implementation of button debouncer.
//
// ----
//
// You must provide a config file debo_config.h (next to your main.c)
//
// Example:
// #pragma once
// #define DEBO_CHANNELS 2
// #define DDEBO_TICKS 5
//
// ----
//
// A pin is registered like this:
//
// #define BTN1 B,0
// #define BTN2 B,1
//
// debo_add(BTN0); // The function returns number assigned to the pin (0, 1, ...)
// debo_add_rev(BTN1); // active low
// debo_register(&PINB, PB2, 0); // direct access - register, pin & invert
//
// Then periodically call the tick function (perhaps in a timer interrupt):
//
// debo_tick();
//
// To check if input is active, use
//
// debo_get_pin(0); // state of input #0 (registered first)
// debo_get_pin(1); // state of input #1 (registered second)
//
----
You must provide a config file debo_config.h (next to your main.c)
Example:
#pragma once
#define DEBO_CHANNELS 2
#define DDEBO_TICKS 5
----
A pin is registered like this:
#define BTN1 B,0
#define BTN2 B,1
debo_add(BTN0); // The function returns number assigned to the pin (0, 1, ...)
debo_add_rev(BTN1); // active low
debo_register(&PINB, PB2, 0); // direct access - register, pin & invert
Then periodically call the tick function (perhaps in a timer interrupt):
debo_tick();
To check if input is active, use
debo_get_pin(0); // state of input #0 (registered first)
debo_get_pin(1); // state of input #1 (registered second)
*/
#include <avr/io.h> #include <avr/io.h>
#include <stdbool.h> #include <stdbool.h>

@ -1,8 +1,8 @@
#pragma once #pragma once
/* //
HSL support (addition to colors.h) // HSL support (addition to colors.h)
*/ //
#include "colors.h" #include "colors.h"

@ -1,24 +1,22 @@
#pragma once #pragma once
/* // HD44780 LCD display driver - 4-bit mode
HD44780 LCD display driver - 4-bit mode //
// LCD pins are configured using a file lcd_config.h, which you
LCD pins are configured using a file lcd_config.h, which you // have to add next to your main.c file.
have to add next to your main.c file. //
// Content can be something like this:
Content can be something like this: //
// #pragma once
#pragma once // #include "lib/arduino_pins.h"
#include "lib/arduino_pins.h" // #define LCD_RS D10
#define LCD_RS D10 // #define LCD_RW D11
#define LCD_RW D11 // #define LCD_E D12
#define LCD_E D12 // #define LCD_D4 D13
#define LCD_D4 D13 // #define LCD_D5 D14
#define LCD_D5 D14 // #define LCD_D6 D15
#define LCD_D6 D15 // #define LCD_D7 D16
#define LCD_D7 D16 //
*/
#include <stdint.h> #include <stdint.h>
#include "lcd_config.h" #include "lcd_config.h"

@ -1,8 +1,8 @@
#pragma once #pragma once
/** //
Custom loops // Custom loops
*/ //
// Repeat code n times (uint8_t counter) // Repeat code n times (uint8_t counter)
#define repeat(count) repeat_aux(count, _repeat_##__COUNTER__) #define repeat(count) repeat_aux(count, _repeat_##__COUNTER__)

@ -1,6 +1,6 @@
#pragma once #pragma once
/** Weird constructs for the compiler */ // Weird constructs for the compiler
// general macros // general macros
#define SECTION(pos) __attribute__((naked, used, section(pos))) #define SECTION(pos) __attribute__((naked, used, section(pos)))

@ -1,8 +1,8 @@
#pragma once #pragma once
/** //
Functions for precise delays (nanoseconds / cycles) // Functions for precise delays (nanoseconds / cycles)
*/ //
#include <avr/io.h> #include <avr/io.h>
#include <util/delay_basic.h> #include <util/delay_basic.h>

@ -1,30 +1,30 @@
#pragma once #pragma once
/** //
This file provides macros for pin manipulation. // This file provides macros for pin manipulation.
//
You can define your application pins like so: // You can define your application pins like so:
//
// Led at PORTB, pin 1 // // Led at PORTB, pin 1
#define LED B,1 // #define LED B,1
//
// Switch at PORTD, pin 7 // // Switch at PORTD, pin 7
#define SW1 D,7 // #define SW1 D,7
//
Now you can use macros from this file to wirh with the pins, eg: // Now you can use macros from this file to wirh with the pins, eg:
//
as_output(LED); // as_output(LED);
as_input(SW1); // as_input(SW1);
pullup_on(SW1); // pullup_on(SW1);
//
toggle_pin(LED); // toggle_pin(LED);
while (pin_is_low(SW1)); // while (pin_is_low(SW1));
//
- The macros io2XXX() can be used to get literal name of register associated with the pin. // - The macros io2XXX() can be used to get literal name of register associated with the pin.
- io2n() provides pin number. // - io2n() provides pin number.
- The XXX_aux() macros are internal and should not be used elsewhere. // - The XXX_aux() macros are internal and should not be used elsewhere.
- The io_pack() macro is used to pass pin (io) to other macro without expanding it. // - The io_pack() macro is used to pass pin (io) to other macro without expanding it.
*/ //
#include <avr/io.h> #include <avr/io.h>
#include "calc.h" #include "calc.h"

@ -1,11 +1,11 @@
#pragma once #pragma once
/* //
Utilities for UART communication. // Utilities for UART communication.
//
First, init uart with desired baud rate using uart_init(). // First, init uart with desired baud rate using uart_init().
Then, enable interrupts you want, and that's it. // Then, enable interrupts you want, and that's it.
*/ //
#include <avr/io.h> #include <avr/io.h>
#include <avr/pgmspace.h> #include <avr/pgmspace.h>

@ -0,0 +1,166 @@
#include <avr/io.h>
#include <stdbool.h>
#include <stdint.h>
#include "uart.h"
#include "uart_ansi.h"
void vt_goto(uint16_t x, uint16_t y)
{
uart_putc(27);
uart_putc('[');
uart_putu(x);
uart_putc(';');
uart_putu(y);
uart_putc('H');
}
void vt_move(int16_t x, int16_t y)
{
vt_move_x(x);
vt_move_y(y);
}
void vt_move_x(int16_t x)
{
if (x < 0) {
vt_left(-x);
} else {
vt_right(x);
}
}
void vt_move_y(int16_t y)
{
if (y < 0) {
vt_up(-y);
} else {
vt_down(y);
}
}
void vt_up(uint16_t y)
{
if (y == 0) return;
uart_putc(27);
uart_putc('[');
uart_putu(y);
uart_putc('A');
}
void vt_down(uint16_t y)
{
if (y == 0) return;
uart_putc(27);
uart_putc('[');
uart_putu(y);
uart_putc('B');
}
void vt_left(uint16_t x)
{
if (x == 0) return;
uart_putc(27);
uart_putc('[');
uart_putu(x);
uart_putc('D');
}
void vt_right(uint16_t x)
{
if (x == 0) return;
uart_putc(27);
uart_putc('[');
uart_putu(x);
uart_putc('C');
}
void vt_scroll(int16_t y)
{
while (y < 0) {
uart_putc(27);
uart_putc('D'); // up
y++;
}
while (y > 0) {
uart_putc(27);
uart_putc('M'); // down
y--;
}
}
void vt_save()
{
uart_putc(27);
uart_putc(7);
}
void vt_restore()
{
uart_putc(27);
uart_putc(8);
}
void vt_style(uint8_t flags)
{
if (flags == VT_NORMAL) {
uart_puts("\x1B[m"); // reset
return;
}
if (flags & VT_BOLD) {
uart_puts("\x1B[1m");
}
if (flags & VT_UNDERLINE) {
uart_puts("\x1B[4m");
}
if (flags & VT_BLINK) {
uart_puts("\x1B[5m");
}
if (flags & VT_REVERSE) {
uart_puts("\x1B[7m");
}
if (flags & VT_HIDDEN) {
uart_puts("\x1B[8m");
}
}
void vt_color(uint8_t fg, uint8_t bg)
{
uart_putc(27);
uart_putc('[');
uart_putu(fg);
uart_putc(';');
uart_putu(bg);
uart_putc('m');
}
void vt_clear()
{
uart_puts("\x1B[2J");
}
void vt_home()
{
uart_puts("\x1B[H");
}

@ -0,0 +1,62 @@
#pragma once
//
// ANSI / VT100 utilities for UART
//
#include <avr/io.h>
#include <stdbool.h>
#include <stdint.h>
#include "uart.h"
#define VT_NORMAL 0
#define VT_BOLD 1
#define VT_UNDERLINE 2
#define VT_BLINK 4
#define VT_REVERSE 8
#define VT_HIDDEN 16
/** Jump to a location on the screen */
void vt_goto(uint16_t x, uint16_t y);
/** Move cursor relative to current location */
void vt_move(int16_t x, int16_t y);
/** Move cursor horizontally */
void vt_move_x(int16_t x);
/** Move cursor vertically */
void vt_move_y(int16_t y);
/** Move cursor up y cells */
void vt_up(uint16_t y);
/** Move cursor down y cells */
void vt_down(uint16_t y);
/** Move cursor left x cells */
void vt_left(uint16_t x);
/** Move cursor right x cells */
void vt_right(uint16_t x);
/** Scroll y lines down (like up/down, but moves window if needed) */
void vt_scroll(int16_t down);
/** Set font style */
void vt_style(uint8_t flags);
/** Set color */
void vt_color(uint8_t fg, uint8_t bg);
/** Save cursor position & text attributes */
void vt_save();
/** Restore cursor to saved values */
void vt_restore();
/** Clear the screen */
void vt_clear();
/** Move cursor to top left corner */
void vt_home();

@ -1,21 +1,20 @@
#pragma once #pragma once
/** //
Utils for driving a WS28xx (tested on WS2812B) RGB LED strips. // Utils for driving a WS28xx (tested on WS2812B) RGB LED strips.
//
It's implemented as macros to avoid overhead when passing values, and to // It's implemented as macros to avoid overhead when passing values, and to
enable driving multiple strips at once. // enable driving multiple strips at once.
//
To avoid bloating your code, try to reduce the number of invocations - // To avoid bloating your code, try to reduce the number of invocations -
compute color and then send it. // compute color and then send it.
//
[IMPORTANT] // [IMPORTANT]
//
Some seemingly random influences can ruin the communication. // Some seemingly random influences can ruin the communication.
If you have enough memory, consider preparing the colors in array, // If you have enough memory, consider preparing the colors in array,
and sending this array using one of the "ws_send_XXX_array" macros. // and sending this array using one of the "ws_send_XXX_array" macros.
//
*/
#include <avr/io.h> #include <avr/io.h>

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